SE505060C2 - Centrifuge device with rotatable cross arm - Google Patents

Abstract

PCT No. PCT/SE95/01036 Sec. 371 Date Jun. 12, 1997 Sec. 102(e) Date Jun. 12, 1997 PCT Filed Sep. 14, 1995 PCT Pub. No. WO96/08314 PCT Pub. Date Mar. 21, 1996A centrifuge for rotating test tubes and the like about a rotational axis includes a drive shaft and a plurality of handles connected thereto to support respective test tube attachments. Each test tube attachment includes two concentric rings, an outer ring pivotally connected to the handle by two diametrically opposed radial pivots and an inner ring pivotally connected to the outer ring by two radial pivots arranged perpendicular to the other radial pivots. The inner ring seats an axial bearing which rotatably supports a container capable of holding in place a test tube.

Description

a25 505 060 VarVtal.

SE-C-129311 describes a cardan-type centrifuge which allows rapid acceleration and deceleration without adversely affecting the sedimentation or alignment of small amounts of material up to 100 milliliters. In larger volumes, a rapid deceleration results in a vortex formation, as the material will rotate in the tube. The eddy currents in the sample material cause a certain part of the liquid to become cloudy during the deceleration phase of the centrifuge.

Another disadvantage of centrifugation with conventional cylindrical centrifuge tubes is that some of the sediment sticks to the upper part of the centrifuge tube instead of accumulating at the bottom thereof.

END OF THE INVENTION ocu MOST IMPORTANT CHARACTERISTICS The object of the present invention is to provide a centrifuge in which, even with a relatively rapid deceleration thereof, the centrifugation result is to be obtained. Another object of the invention is that no eddy currents occur which impair the design of the centrifuge tubes so that denser material will not be but to the bottom portion of the 100 centrifuge tube. The adhesion to the tube walls is practically centrifuged down to the first-mentioned purpose. The centrifuge tubes are arranged rotatably about their own longitudinal axis by achieving Boundary lines along at least a part of their length, which extension lines, when the centrifuge tube is in horizontal centrifugal stirring position, meet at a point substantially located in the center position of the drive shaft.

DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below with reference to the accompanying drawings, which show some embodiments.

Figs. 1-4 show in perspective the rotor of the centrifuge with its movable sleeves and in these inserted centrifuge tubes in different states, where Fig. 1 shows the rotor in idle position, Fig. 2 in acceleration position, Fig. 3 in its optimum operating position and deceleration mode.

Fig. 5 shows on a larger scale a part of the centrifuge's crossbow in top view.

Fig. 6 shows on an even larger scale a section along the line VI-VI in Fig. 5.

Fig. 7.8 shows in side view the centrifuge tube according to two different variants in optimal operating position (the same figure can be used for top view).

DESCRIPTION OF EMBODIMENTS Figures 1-6 show a rotor of a centrifuge which is not further damaged, and which consists of a drive shaft 12 and, an arm cross 13, which in the embodiment shown comprises four forks 14 for receiving as many movable members 15 of the gimbal type , which in turn each carry their own sleeve or container 16. The movable members 15 comprise two concentric rings, a first inner ring 17, which is movable about two diametrically opposite radial pins 18 arranged in a second outer ring 19. This in turn is movable around two radial pins 20, arranged perpendicular to the pins 18 and mounted in the cross of the arm 13, in the cleats 14.

In the embodiment according to Fig. 6, the inner ring 17 is provided with a shoulder 21, on which rests an axial bearing 22, which is axial in relation to the ring 17 and the sleeve 16, respectively. This is suitably formed with a flange 23 at the opening 24 of the sleeve and which flange abuts against the upper bearing ring of the axial bearing 22.

In each sleeve 16 is insertable a centrifuge tube 25 in which the sample material is placed.

As illustrated in Fig. 1, the rotor of the centrifuge is in the rest position, in which the sleeves 16 assume a vertical position in the forks.

If the centrifuge rotor is accelerated as shown in Fig. 2, the sleeves will move slightly backwards in the direction of movement in the direction of the resultant. This reduces the stress on the centrifuge tubes 25, when exposed to breaking stresses. These non-particles of the sample material move in a direction substantially parallel to the centrifuge tube axis, thereby reducing the risk of the sample material sticking to the walls. In Fig. 3, the rotor has gone up at full speed, with the sleeves 16 assuming a horizontal, radial position. In this the main enrichment takes place. During the deceleration phase, Fig. 4, the rotor is decelerated, whereby the friction in both the drive shaft and the drive motor causes the sleeves 16 to adjust at an angle forward in the direction of movement. Through the gimbal suspension 10 50, the sleeves during this phase can follow the resultant of the influencing forces, whereby a part of the harmful eddy current formation in the centrifuge tube is counteracted. The residual vortex formation produced during braking is eliminated by the sleeves 16 and thus the centrifuge tube 25 being rotatable about their own longitudinal axis. Since it is a question of relatively small forces which set the sample material in rotation, it is required that the sleeve 16 with the centrifuge tube 25 be easily brought into rotation, which has been produced by the axial bearing 22.

It can be mentioned that the orientation, sedimentation and appearance of different cells, especially cancer cells and inflammatory cells, precede the centrifugation process. Since the content of solid particles is often affected by different forces - during and after and cells in the sample liquid can be very small, it is of utmost importance that sedimented material is not lost and becomes adherent to the walls of the centrifuge tube. By practically all the material ends up in the bottom of the centrifuge tube, the centrifugation result is improved and the diagnostic safety is increased.

Until now, centrifuge tubes with a cylindrical shape have mainly been used, which, however, have the disadvantage that a particle deposition takes place on the inside of the tube mainly within the upper part and thus cannot get down to the bottom of the tube, where the particles are preferred. collect as large a part as possible of the denser In addition, poorer enrichment to the upper liquid surface is obtained by less dense particles at cylindrical pipes, as these have a relatively at the upper opening.

It has now been found that if the centrifuge tube 25 is formed with inner boundary lines converging towards its upper opening, its extension 28, when the centrifuge tube assumes a horizontal centrifugal position, coincides at a point substantially located on the center line of the drive shaft 12, then these disadvantages so that during centrifugation denser particles do not stick to the upper inner surface of the centrifuge tube but are centrifuged down to the bottom of the tube.

At the upper surface of the liquid in the centrifuge tube, due to the upwardly conical shape of the tube, an enrichment of less dense particles is obtained to a small surface, which facilitates the sampling of e.g. bacterial samples in tuberculosis, as samples must be taken from both the surface and bottom of the centrifuge tube.

As can be seen from Fig. 7 (an embodiment), the centrifuge tube is the bottom, generatris, which passes through a point on the center line of the drive shaft along its entire length, until then formed by a 12 and which forms a conical surface.

The embodiment variant shown in Fig. 8 differs from the centrifuge tube shown in Fig. 7 in that it is easily provided in its upper part with a cylindrical neck 26, for the application of a plug 27.

The centrifuge tube 25 can also be designed as a tube open at both ends, both of which can be sealed by means of a plug each. The conicity in the centrifuge tube does not have to extend over the entire length of the tube and the tube can also be designed with double conicity, which tapers in the direction towards both ends. 505 060 7 The centrifuge tube can be made of different materials, for example glass, plastic, metal, of disposable type, e.g. paper or the like. It can also be designed as a bag in a conical shape with associated holder. The tapered centrifuge tube may have a supporting flange at the opening and / or along the outer side supporting wings.

Claims (3)

10 15 20 25 30 35 505 060 PATENT REQUIREMENTS 1. Device for centrifuges for e.g. medical and research laboratories, comprising an arm cross (13) or the like rotatable by a vertical drive shaft (12), in which sleeves (16) are mounted via movable members (15) for receiving centrifuge tubes (25), which sleeves are centrifuged. are freely adjustable in the direction of the resultant of the forces acting on the respective sleeve, characterized in that the sleeves (16) and thus the centrifuge tubes (25) are arranged rotatable about their own longitudinal axis under the influence of these retarding forces acting on braking of the centrifuge. , each member (15) being constituted by two concentric rings (17, 19), a first inner ring (17) movable about two diametrically opposite radial pins (18) arranged in a second outer ring (19), which in turn (20), perpendicular to the former and mounted in the arm cross (13), and is movable around two radial pins arranged first inner arranged one that at that ring (17) is axial bearing (22) for supporting saw the sleeve (16). Device according to claim 1, characterized in that the centrifuge tube (25) is formed with converging inner boundary lines along at least a part, preferably an upper part of its length, which extension (28) of boundary lines, when the centrifuge tube (25) is in a horizontal centrifugation position, meeting at a point substantially located on the center line of the drive shaft (12). 505 060 ' Device according to claims 1 and 2, characterized in that the centrifuge tube is designed as a bag with a conical shape and associated bag holder.